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Advanced MoSe2/Carbon Electrodes in Li/Na‐Ions Batteries
Advanced Materials Interfaces ( IF 4.3 ) Pub Date : 2019-12-20 , DOI: 10.1002/admi.201901651 Peng Ge 1 , Limin Zhang 1 , Yue Yang 1 , Wei Sun 1 , Yuehua Hu 1 , Xiaobo Ji 2
Advanced Materials Interfaces ( IF 4.3 ) Pub Date : 2019-12-20 , DOI: 10.1002/admi.201901651 Peng Ge 1 , Limin Zhang 1 , Yue Yang 1 , Wei Sun 1 , Yuehua Hu 1 , Xiaobo Ji 2
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Secondary charge batteries have captured numerous attentions, owing to their abundant raw, portability, and high energy density. As the main ions‐storage carrier, the electrode materials serve vital roles on the properties of whole battery system. Currently, MoSe2 is regarded as rising star of transition metal dichalcogenides, displaying unique layered structure, high electronic conductivity, as well as narrow energy band. These advantages enable their widely application on hydrogen evolution reactions and solar cells. Recently, a plenty of researching activities on MoSe2/carbon are triggered due to large interplanar spacing and high ions/e− migration rate. In this review, the recent achievements of diverse MoSe2/carbon on great energy‐storage domains are solidly summarized from bonding types (surface‐loading, internal‐wrapped) and dimensional controlling (1D nanotubes/nanofibers, 2D graphene/nanosheets, 3D carbon framework/sphere). Meanwhile, the related Li/Na ions‐storage mechanisms are also concluded. Furthermore, for MoSe2/carbon with better electrochemical properties, the opportunities and perspectives in the future are also suggested. This review throws light on the systematic developments of advanced MoSe2/carbon, and confirms its exploring potential on lithium‐ion batteries/sodium‐ion batteries.
中文翻译:
锂/钠离子电池中的高级MoSe2 /碳电极
二次充电电池由于其丰富的原始性,便携性和高能量密度而备受关注。作为主要的离子存储载体,电极材料对整个电池系统的性能起着至关重要的作用。目前,MoSe 2被认为是过渡金属二卤化物的后起之秀,具有独特的层状结构,高电子电导率和窄能带。这些优点使得它们可以广泛地用于氢释放反应和太阳能电池。近来,大量的上MOSE研究活动的2 /碳被触发由于大的晶面间距和高离子/ E -的迁移率。在这篇评论中,多样化的MoSe 2的最新成就从键合类型(表面加载,内部包裹)和尺寸控制(1D纳米管/纳米纤维,2D石墨烯/纳米片,3D碳骨架/球体)牢固地总结了大型储能领域中的/碳。同时,还总结了相关的Li / Na离子存储机理。此外,对于具有更好电化学性能的MoSe 2 /碳,还提出了未来的机会和前景。这篇综述揭示了先进的MoSe 2 /碳的系统开发,并确认了其在锂离子电池/钠离子电池上的探索潜力。
更新日期:2019-12-20
中文翻译:
锂/钠离子电池中的高级MoSe2 /碳电极
二次充电电池由于其丰富的原始性,便携性和高能量密度而备受关注。作为主要的离子存储载体,电极材料对整个电池系统的性能起着至关重要的作用。目前,MoSe 2被认为是过渡金属二卤化物的后起之秀,具有独特的层状结构,高电子电导率和窄能带。这些优点使得它们可以广泛地用于氢释放反应和太阳能电池。近来,大量的上MOSE研究活动的2 /碳被触发由于大的晶面间距和高离子/ E -的迁移率。在这篇评论中,多样化的MoSe 2的最新成就从键合类型(表面加载,内部包裹)和尺寸控制(1D纳米管/纳米纤维,2D石墨烯/纳米片,3D碳骨架/球体)牢固地总结了大型储能领域中的/碳。同时,还总结了相关的Li / Na离子存储机理。此外,对于具有更好电化学性能的MoSe 2 /碳,还提出了未来的机会和前景。这篇综述揭示了先进的MoSe 2 /碳的系统开发,并确认了其在锂离子电池/钠离子电池上的探索潜力。
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